A novel analog-to-digital conversion pre-processor uses a modulo-based signal folding method to overcome the limited dynamic range of conventional ADCs. The folded signal is reconstructed using a dedicated unfolding algorithm, enabling precise signal recovery across a wide amplitude spectrum. ... Read more

Quantum computing platforms based on superconducting qubits suffer from high error rates and short storage time of only a few milliseconds, limiting scalable computations. ... Read more

Modern ADCs must reduce cost and power consumption without compromising signal quality, particularly in power-sensitive systems such as wearables, IoT, and security devices. This technology introduces the first sub-Nyquist ADC based on an integrate-and-fire time encoding machine (IF-TEM). ... Read more

Current contact-based monitoring devices cause patient discomfort, increase infection risks, and demand significant medical staff time. ... Read more

This task-specific MIMO system enables highly accurate signal recovery with minimal hardware complexity and power consumption. It combines task-specific beamforming, low-bit ADCs, and quantized analog combiners to efficiently leverage signal sparsity and suppress spatial interference. ... Read more

Standard light microscopy generates flat, two-dimensional images of transparent specimens, making it difficult to resolve the spatial arrangement of internal structures. Existing methods to infer depth rely on multiple recordings or complex hardware adjustments, often resulting in inaccuracies. ... Read more

Quantum computing requires reliable control and braiding of Majorana zero modes. These modes emerge in topological superconductors and enable exceptionally stable quantum operations but are highly sensitive to noise and geometric imperfections. ... Read more

Realizing topological superconductivity and stable Majorana zero modes, which are envisioned for use in topological quantum computers, typically requires large magnetic fields (around .1 T). However, these strong magnetic fields can suppress superconductivity and hinder device integration. ... Read more

An innovative method to generate spin current and magnetoresistance by leveraging the Orbital Hall Effect (OHE). This approach utilizes ordinary metals like Aluminum and Copper, combined with a thin layer of heavy metal to convert orbital currents into spin currents. ... Read more

Conventional methods for magnetization control rely on magnetic materials and electrical currents, limiting miniaturization, energy efficiency, and operational speed. ... Read more